子分类:
- C04B41/5001: ...{碳或可碳化材料}
- C04B41/5006: ...{硼化合物}
- C04B41/5007: ...{盐或含盐成分,如盐釉 (C04B41/5006 优先)}
- C04B41/5016: ...{酸}
- C04B41/5018: ...{氟化合物}
- C04B41/502: ...{水}
- C04B41/5022: ...{玻璃质材料 (玻璃质上釉和瓷釉入 C03C; 陶瓷色素入 C09C1/0009)}
- C04B41/5024: ...{硅酸盐 (C04B41/5022 优先; 氟 化硅入 C04B41/5018)}
- C04B41/5025: ...{陶瓷材料 (氧化铜或其固体溶液入 C04B41/5074)}
- C04B41/5053: ...{非氧化物陶瓷 (碳或可碳化材料入 C04B41/5001)}
- C04B41/5072: ...{不包括在C04B41/5025 的氧化物或氢 氧化物(C04B40/0236 优先; 氧化硼入 C04B41/5006)}
- C04B41/5076: ...{通过无机结合剂与大块黏结 (硫成分入C04B41/5097)}
- C04B41/5093: ...{不同于金属或碳的单质 (氟气处理入 C04B41/5019)}
- C04B41/5098: ...{金属陶瓷}
- C04B41/51: ...金属化, {如烧结的陶器粗成品与 熔化金属的渗透(一般的金属材料入 C23C; 含游离金属与碳化物, 钻石,氧化物,硼化物,氮化物, 硅化物,如金属陶瓷或者气体金属 化合物,如氮氧化物或硫化物,除 可见的修补剂外入 C22C; 含游离 金属的粗成品的渗透,如金属陶瓷入 C22C)}
| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 121 | 室内工程建筑的方法、组件和附加层 | CN01813611.7 | 2001-07-31 | CN1460092A | 2003-12-03 | F·图贝; C·勒克莱尔; P·布尔-沙泰尔; E·A·科尔伯特; P·加恩; R·鲍彻; S·比洛多 |
| 本发明提供用于室内工程的建筑组件,该组件包括预制装配构件,比如石膏纤维板,和至少一种接合材料,比如密封层,其中所述预制装配构件包括在所述预制装配构件上涂布的由至少一种极薄涂膜形成的涂层;该密封层把相邻的所述预制装配构件接合在一起,形成实质上平整的,包括所述至少一种接合材料的可见表面和涂有极薄涂膜的预制装配构件的可见表面的外表面;其中所述至少一种接合材料和所述至少一种极薄涂膜都含有无机填料、粘合剂和水;而且其中所述至少一种接合材料和所述至少一种极薄涂膜的组成互相匹配,由此所述至少一种极薄涂膜互相匹配,由此使所述至少一种接合材料和所述极薄涂膜,均处于干态时,形成实质上均匀的表面,而且由此外表面易于进行装饰。 | ||||||
| 122 | 包含防水层的混凝土结构及形成该结构的方法 | CN97192061.3 | 1997-12-01 | CN1116248C | 2003-07-30 | K·迪斯舍; M·奥普利格 |
| 形成一种防水混凝土结构的方法,包括如下步骤:(a)在载体上涂布一层混凝土组合物;(b)在上述混凝土组合物上喷涂一防水层,并(c)在防水层上再涂布一层混凝土组合物;其特征在于防水层是由组合物提供的,该组合物含有可聚结的热塑性聚合物颗粒的水分散体。本方法可用于解决隧道衬里防水的问题。 | ||||||
| 123 | 皮江法炼镁渣制砖制备方法 | CN02135468.5 | 2002-09-07 | CN1401605A | 2003-03-12 | 朱广东 |
| 一种皮江法炼镁渣制砖制备方法,主要解决现有皮江法金属镁冶炼渣和烟气没有被利用,造成环境污染的问题。其制备方法是将炼镁渣从还原罐中铲出,自然冷却至常温,然后给炼镁渣加入50~60%的水,混合;将混合后的渣料在常温下放置一周,送入制砖机中成型;成型后的砖坯送入碳化室中,被白云石煅烧后产生的二氧化碳烟气进行碳化,即成为产品。用本方法制砖,可以充分利用现有皮江法金属镁冶炼过程中产生的渣和烟气,由于将废渣和废气综合利用制成建筑材料,减少了排渣所占耕地以及对环境的污染,同时又减少了二氧化碳向大气的排放数量,降低了二氧化碳对大气产生的温室效应的影响。 | ||||||
| 124 | 一种改进固化水泥产品的方法 | CN96194546.X | 1996-06-03 | CN1046690C | 1999-11-24 | R·H·琼斯 |
| 令固化的水泥基质与高压密相或超临界CO2接触,超临界CO2通过基质通道进入基质,中和水泥固有的碱度,使不耐碱材料可加入水泥。CO2将水泥中氢氧化钙转变成碳酸钙和水,而密相或超临界CO2的高压力形成圆形紧密堆积排列的晶粒,其间很少或没有可见的孔和毛细管,增强了固化水泥的均匀性,强度和其与未涂布的增强玻璃纤维的结合。超临界CO2可将溶解或悬浮的有机或无机材料,包括粉末化金属,传递入水泥基质的内部,改变其化学和/或物理特性。 | ||||||
| 125 | 高强开孔泡沫陶瓷和其制备方法 | CN97195118.7 | 1997-05-30 | CN1220649A | 1999-06-23 | 约格尔·阿德莱尔; 迈克尔·泰希格拉伯; 吉泽拉·施坦得克; 赫尔穆特·尧尼奇; 海克·斯托弗; 莱因哈德·施托泽尔 |
| 本发明涉及陶瓷领域,涉及可作袋式过滤器使用的高强开孔泡沫陶瓷和它们的制备方法。本发明的目的是用一种简单和价廉物美的方法制备具有改进强度的泡沫陶瓷。本发明的目的通过开孔陶瓷泡沫解决,其中用一种或多种金属和/或陶瓷相和/或玻璃相完全或部分填充陶瓷体的内部空腔,陶瓷体的裂纹和陶瓷体的气孔。此外,制备本发明的开孔泡沫陶瓷,其中,在烧结期间或之后,用一种熔融物或一种悬浮液完全或部分填充陶瓷体的空腔,裂纹和气孔,其中将熔融物和悬浮液熔化到泡沫陶瓷熔融温度以下的温度,它们具有与泡沫陶瓷相似的膨胀系数,并具有极好的润湿性,而且不会或者部分与泡沫陶瓷组分进行反应。 | ||||||
| 126 | 用高压CO2处理的水泥 | CN96194546.X | 1996-06-03 | CN1187179A | 1998-07-08 | R·H·琼斯 |
| 令固化的水泥基质与高压密相或超临界CO2接触,超临界CO2通过基质通道进入基质,中和水泥固有的碱度,使不耐碱材料可加入水泥。CO2将水泥中氢氧化钙转变成碳酸钙和水,而密相或超临界CO2的高压力形成圆形坚密堆积排列的晶粒,其间很少或没有可见的孔和毛细管,增强了固化水泥的均匀性,强度和其与未涂布的增强玻璃纤维的结合。超临界CO2可将溶解或悬浮的有机或无机材料,包括粉末化金属,传递入水泥基质的内部,改变其化学和/或物理特性。 | ||||||
| 127 | 烟囱防蚀保护剂 | CN92106790.9 | 1992-11-12 | CN1086834A | 1994-05-18 | 辛益群 |
| 一种烟囱防蚀保护剂,涂覆于烟囱的触烟表面,可与腐蚀烟囱的有害物质发生化学反应,形成无害的物质,并于烟囱的触烟表面形成保护膜,从而大大延长烟囱的使用寿命。 | ||||||
| 128 | 陶瓷釉中彩一次烧成工艺 | CN91109069.X | 1991-09-18 | CN1070629A | 1993-04-07 | 张新才 |
| 陶瓷釉中彩一次烧成工艺,特别适用于日用陶瓷及建筑陶瓷制品的装饰。其特征在于,制作色料是将不同颜色的色基分别与添加剂混合入磨湿混,烧成后细磨烘干备用。添加剂由石英、长石、粘土、石灰石、瓷粉、滑石、骨灰及金属氧化物组成。色料与添加剂按一定比例配合使用。贴花粘接剂由甲基纤维素、水、工业酒精组成,一次烧成温度在1180—1320℃之间。本发明具有彻底消除铅、镉溶出,降低成本等特点。 | ||||||
| 129 | 微晶花岗石的配制方法 | CN92105692.3 | 1992-07-21 | CN1069957A | 1993-03-17 | 钱宏毅 |
| 本发明提供了一种以水泥、花岗石粉和黄色剂为载体,以玻璃颗粒和低熔点玻璃粉为填充料的微晶花岗石的配制方法。它与现有的合成花岗石相比具有成本低、硬度高、表面有天然花岗石的纹理和色泽,易于批量生产等优点,是一种美观实用的新建材。 | ||||||
| 130 | ADHESION PROMOTER BETWEEN OXIDE CERAMIC AND A VENEER MATERIAL, IN PARTICULAR FOR DENTAL PURPOSES, METHOD FOR THE USE THEREOF AND KIT FOR THE PRODUCTION AND APPLICATION THEREOF | PCT/DE2010001262 | 2010-11-01 | WO2011050786A2 | 2011-05-05 | GLUECK OLAF; GOEBEL ROLAND |
| The aim of the invention is to improve the bond between the oxide ceramic and the veneer material and to increase the durability of said bond. According to the invention, an adhesion promoter (mixture of silicate ceramic and quartz) is applied as a sol to a main body that is to be veneered and that has not yet been densely sintered, the main body being made of oxide ceramic or starting materials thereof. The main body is then sintered to a final state together with the worked-in adhesion promoter, and afterwards the veneer material is applied. The invention is used, for example, to produce dental crowns and bridges having a high load-bearing capacity. | ||||||
| 131 | METHOD, ASSEMBLY AND ADDITIONAL COAT FOR THE CONSTRUCTION OF INTERIOR WORKS | PCT/EP0109336 | 2001-07-31 | WO0212144A9 | 2003-05-15 | ZUBER FRANCOIS; LECLERCQ CLAUDE; BOURNE-CHASTEL PASCAL; COLBERT ELIZABETH A; GAGNE PIERRE; BOUCHER ROLAND; BILODEAU SYLVIE |
| The present invention provides a construction assembly for interior works, comprising: prefabricated elements, e.g. gypsum fiberboards, wherein said prefabricated elements comprise a coating layer formed of at least one skim coat deposited on said prefabricated elements; and at least one jointing material, e.g. a sealing coat, which joints adjacent said prefabricated elements to form a substantially plane outer surface comprising the visible surface of said at least one jointing material and the visible surface of the skim coated prefabricated elements, wherein said at least one jointing material and said at least one skim coat comprise a mineral filler, a binder and water; and wherein the composition of said at least one jointing material and said at least one skim coat are adapted to each other, whereby said at least one skim coat are adapted to each other, whereby said at least one jointing material and said skim coat form, both in a dry state, a substantially homogeneous surface and whereby said outer surface is ready to be decorated. | ||||||
| 132 | METHOD OF PROVIDING A PROTECTIVE COATING COMPOSITION FOR MOLTEN ALUMINUM AND ALKALI METAL ENVIRONMENTS | US15439885 | 2017-02-22 | US20180044540A1 | 2018-02-15 | Madjid Soofi; Lara BINZ; Michael W. Anderson |
| The invention is directed to a method of providing a protective coating composition that protects a refractory wall or lining from chemical attack by molten aluminum and molten alkali metals. The method includes the steps of coating a refractory wall or liner with an aqueous protective composition that includes, by weight of the solids, about 20-90% Al2O3 (excluding calcined alumina), about 15-55% SiO2 and about 1-15% of a metallic non-wetting agent; and evaporating the water before contacting the protective coating with the reactive molten metal. | ||||||
| 133 | High Temperature Composites With Enhanced Matrix | US15168522 | 2016-05-31 | US20170342844A1 | 2017-11-30 | Wayde R. Schmidt; Paul Sheedy; Neal Magdefrau |
| A composite article comprises a substrate, the substrate comprising a silicon containing material and an additive comprising boron nitride nanotubes. | ||||||
| 134 | GALVANIC ANODE SYSTEM FOR THE CORROSION PROTECTION OF STEEL IN CONCRETE | US15322308 | 2015-06-29 | US20170137948A1 | 2017-05-18 | Wolfgang SCHWARZ |
| A galvanic anode system for the corrosion protection of steel in concrete includes a galvanic anode material, which includes of zinc and alloys thereof, embedded in a solid electrolyte, and is characterized in that the galvanically available surface is larger, preferably at least twice as large, as the total geometrical surface of the metal anode. The galvanic anode system is also characterized in that, during operation, during which the anode disintegrates as a sacrificial anode, the galvanically active anode surface is reduced only slightly, preferably is not reduced up to at least 50%, in particular 75%, of the time during use. | ||||||
| 135 | COATING INTERFACE | US15273095 | 2016-09-22 | US20170121232A1 | 2017-05-04 | Scott Nelson; Raymond J. Sinatra; Sean E. Landwehr; Mike R. Dunkin; Ashley Moretti |
| In some examples, the disclosure describes an article and a method of making the same that includes a substrate including a ceramic or a ceramic matrix composite including silicon carbide, where the substrate defines an outer substrate surface and a plurality of grooves formed in the outer substrate surface, where each respective groove of the plurality of grooves exhibits an anchor tooth that spans an edge of the respective groove, and where the plurality of grooves define an average groove width less than about 20 micrometers, and a coating formed on the outer surface of the substrate, where the coating at least partially fills the plurality of grooves of the substrate. | ||||||
| 136 | Method for applying sealing material paste to peripheral surface of ceramic block | US14495896 | 2014-09-25 | US09610606B2 | 2017-04-04 | Tomohiro Takano; Kazuya Bando |
| A method of manufacturing a honeycomb structured body, includes providing an application jig. A sealing material paste is put on a peripheral surface of a pillar-shaped ceramic block. The application jig is set in such a manner that a first principal surface of the application jig faces upward and a second principal surface of the application jig faces downward. The ceramic block is placed inside a second opening section of the application jig. The ceramic block is passed through an opening section of the application jig so that a face defining the second opening section spreads an entire peripheral surface of the ceramic block with the sealing material paste to manufacture a honeycomb structured body with a peripheral sealing material layer formed on the peripheral surface of the ceramic block. | ||||||
| 137 | SYSTEM FOR THERMALLY ISOLATING A TURBINE SHROUD | US14708336 | 2015-05-11 | US20160333713A1 | 2016-11-17 | Christopher Paul TURA; Dylan James Fitzpatrick |
| In one aspect the present subject matter is directed to a system for thermally isolating a turbine shroud of a turbine shroud assembly. The system includes a shroud support having an inner surface and a turbine shroud that is connected to the shroud support. The turbine shroud includes a hot side surface that is radially spaced from a back side surface. At least a portion of the back side surface is oriented towards the inner surface of the shroud support. The system further includes a coating that is disposed along the back side surface of the turbine shroud. The coating regulates heat transfer from the turbine shroud to the shroud support or other hardware that may surround or be adjacent to the turbine shroud. | ||||||
| 138 | Mineral Precipitation Methods | US15029316 | 2014-10-28 | US20160236943A1 | 2016-08-18 | Edward KAVAZANJIAN; Nasser HAMDAN |
| The present invention provides methods for mineral precipitation of porous particulate starting materials using isolated urease. | ||||||
| 139 | Slurry-based coating restoration | US14213466 | 2014-03-14 | US09387512B2 | 2016-07-12 | Kang N. Lee; Adam Lee Chamberlain; Andrew Joseph Lazur |
| In some examples, a method includes identifying a damaged area in a ceramic matrix composite coating of an in-service component; applying a restoration slurry to the damaged area of the ceramic matrix composite coating, wherein the restoration slurry comprises a liquid carrier and a restoration coating material; drying the restoration slurry to form a dried restoration slurry; and heat treating the dried restoration slurry to form a restored portion of the ceramic matrix composite coating. In some examples, an assembly may include a component including a substrate and a coating on the substrate, where the coating defines a damaged portion; masking around the damaged portion on undamaged portions of the coating; and a restoration slurry in the damaged portion, wherein the restoration slurry comprises a liquid carrier and a restoration coating material. | ||||||
| 140 | BIOCIDAL GLAZING COMPOSITION, METHOD, AND ARTICLE | US14962838 | 2015-12-08 | US20160081349A1 | 2016-03-24 | Alvin Lamar Campbell, JR. |
| A biocidal additive package comprises at least one metal or metal containing compound selected from the group consisting of Cu2O, Cu(OH)2, Cu, CuO3, Cu2O3, and a combination thereof, and at least one non-copper metal or non-copper containing metal compound. Non-limiting examples of non-copper metal and non-copper containing metal compounds are Ag, Ag2O, Bi, Bi2O3, Zn, ZnO, or a combination thereof. A biocidal ceramic glaze layer and an article comprising a biocidal ceramic glaze layer are provided. Also provided is a method of affixing a biocidal ceramic glaze to a substrate. | ||||||
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